Schema-based services for identity-based access to device data

ABSTRACT

A schema-based device service that provides centralized access to per-user device data, wherein access to the device data is based on each user&#39;s identity. The device service includes a schema that defines rules and a structure for each user&#39;s data, and also includes methods that provide access to the data in a defined way. The device schema thus corresponds to a logical document containing the data for each user. A service such as a notification/alerts service accesses data in the logical document by data access requests through defined methods, such as in order to customize or modify a notification for a device based on the device characteristics. In one implementation, the device schemas are arranged as XML documents, and the services provide methods that control access to the data based on the requesting user&#39;s identification, defined role and scope for that role.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 10/099,467, filed Mar. 14, 2002, now U.S. Pat. No. 6,980,993 which is a CIP of U.S. patent application Ser. No. 10/017,680, filed October 22, 2001, which claims priority to U.S. provisional application Ser. No. 60/275,809, filed Mar. 14, 2001.

COPYRIGHT DISCLAIMER

A portion of the disclosure of this patent document contains material that is subject to copyright protection. The copyright owner has no objection to the facsimile reproduction by anyone of the patent document or the patent disclosure as it appears in the Patent and Trademark Office patent file or records, but otherwise reserves all copyright rights whatsoever.

FIELD OF THE INVENTION

The invention relates generally to computer network data access, and more particularly to systems, methods and data structures for accessing data and data-related services over a network.

BACKGROUND OF THE INVENTION

There are many types of data that users need to manage and otherwise access. For example, users keep word processing documents, spreadsheet documents, calendars, telephone numbers and addresses, e-mail messages, financial information and so on. In general, users maintain this information on various personal computers, hand-held computers, pocket-sized computers, personal digital assistants, mobile phones and other electronic devices. In most cases, a user's data on one device is not accessible to another device, without some manual synchronization process or the like to exchange the data, which is cumbersome. Moreover, some devices do not readily allow for synchronization. For example, if a user leaves his cell phone at work, he has no way to get his stored phone numbers off the cell phone when at home, even if the user has a computing device or similar cell phone at his disposal. As is evident, these drawbacks result from the separate devices each containing their own data.

Corporate networks and the like can provide users with remote access to some of their data, but many users do not have access to such a network. For many of those that have access, connecting to a network with the many different types of devices, assuming such devices can even connect to a network, can be a complex or overwhelming problem.

Moreover, even if a user has centrally stored data, the user needs the correct type of device running the appropriate application program to access that data. For example, a user with a PDA that maintains a user's information about that device will not be able to use that information with another device. In general, this is because the data is formatted and accessed according to the way the application program wants it to be formatted.

What is needed is a model wherein data is centrally stored for users, with a set of services that control access to the data with defined methods, regardless of the application program and/or device.

SUMMARY OF THE INVENTION

Briefly, the present invention provides a Device service for central (e.g., Internet) access to per-user device data, based on each user's identity, wherein the device service includes a schema that defines rules and a structure for the data, and also includes methods that provide access to the data in a defined way. Because the structure of the data is defined from the perspective of the data, not from that of an application program or a device, programs can communicate with the services to access the data, with existing knowledge of the format. In one implementation, the device schemas are arranged as XML documents, and the services provide methods that control access to the data based on the requesting user's identification, defined role and scope for that role. In this way, data can be accessed by its owner or a service on its behalf, and shared to an extent determined by the owner. For example, a service such as a notification/alerts service accesses data in the logical document by data access requests through defined methods, such as in order to customize a notification for a device that is to receive the notification, based on the device's characteristics. Extensibility is defined into the schema.

Other benefits and advantages will become apparent from the following detailed description when taken in conjunction with the drawings, in which:

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram representing an exemplary computer system into which the present invention may be incorporated;

FIG. 2 is a block diagram representing a generic data access model in accordance with one aspect of the present invention;

FIG. 3 is a representation of services for identity-based data access in accordance with one aspect of the present invention;

FIG. 4 is a block diagram representing a schema-based service for accessing data arranged in a logical content document based on a defined schema for that service in accordance with one aspect of the present invention; and

FIG. 5 is a block diagram representing devices and web services connected to a device service in accordance with one aspect of the present invention.

DETAILED DESCRIPTION

Exemplary Operating Environment

FIG. 1 illustrates an example of a suitable computing system environment 100 on which the invention may be implemented. The computing system environment 100 is only one example of a suitable computing environment and is not intended to suggest any limitation as to the scope of use or functionality of the invention. Neither should the computing environment 100 be interpreted as having any dependency or requirement relating to any one or combination of components illustrated in the exemplary operating environment 100.

The invention is operational with numerous other general purpose or special purpose computing system environments or configurations. Examples of well known computing systems, environments, and/or configurations that may be suitable for use with the invention include, but are not limited to: personal computers, server computers, hand-held or laptop devices, tablet devices, multiprocessor systems, microprocessor-based systems, set top boxes, programmable consumer electronics, network PCs, minicomputers, mainframe computers, distributed computing environments that include any of the above systems or devices, and the like.

The invention may be described in the general context of computer-executable instructions, such as program modules, being executed by a computer. Generally, program modules include routines, programs, objects, components, data structures, and so forth, that perform particular tasks or implement particular abstract data types. The invention may also be practiced in distributed computing environments where tasks are performed by remote processing devices that are linked through a communications network. In a distributed computing environment, program modules may be located in local and/or remote computer storage media including memory storage devices.

With reference to FIG. 1, an exemplary system for implementing the invention includes a general purpose computing device in the form of a computer 110. Components of the computer 110 may include, but are not limited to, a processing unit 120, a system memory 130, and a system bus 121 that couples various system components including the system memory to the processing unit 120. The system bus 121 may be any of several types of bus structures including a memory bus or memory controller, a peripheral bus, and a local bus using any of a variety of bus architectures. By way of example, and not limitation, such architectures include Industry Standard Architecture (ISA) bus, Micro Channel Architecture (MCA) bus, Enhanced ISA (EISA) bus, Video Electronics Standards Association (VESA) local bus, and Peripheral Component Interconnect (PCI) bus also known as Mezzanine bus.

The computer 110 typically includes a variety of computer-readable media. Computer-readable media can be any available media that can be accessed by the computer 110 and includes both volatile and nonvolatile media, and removable and non-removable media. By way of example, and not limitation, computer-readable media may comprise computer storage media and communication media. Computer storage media includes both volatile and nonvolatile, removable and non-removable media implemented in any method or technology for storage of information such as computer-readable instructions, data structures, program modules or other data. Computer storage media includes, but is not limited to, RAM, ROM, EEPROM, flash memory or other memory technology, CD-ROM, digital versatile disks (DVD) or other optical disk storage, magnetic cassettes, magnetic tape, magnetic disk storage or other magnetic storage devices, or any other medium which can be used to store the desired information and which can accessed by the computer 110. Communication media typically embodies computer-readable instructions, data structures, program modules or other data in a modulated data signal such as a carrier wave or other transport mechanism and includes any information delivery media. The term “modulated data signal” means a signal that has one or more of its characteristics set or changed in such a manner as to encode information in the signal. By way of example, and not limitation, communication media includes wired media such as a wired network or direct-wired connection, and wireless media such as acoustic, RF, infrared and other wireless media. Combinations of the any of the above should also be included within the scope of computer-readable media.

The system memory 130 includes computer storage media in the form of volatile and/or nonvolatile memory such as read only memory (ROM) 131 and random access memory (RAM) 132. A basic input/output system 133 (BIOS), containing the basic routines that help to transfer information between elements within computer 110, such as during start-up, is typically stored in ROM 131. RAM 132 typically contains data and/or program modules that are immediately accessible to and/or presently being operated on by processing unit 120. By way of example, and not limitation, FIG. 1 illustrates operating system 134, application programs 135, other program modules 136 and program data 137.

The computer 110 may also include other removable/non-removable, volatile/nonvolatile computer storage media. By way of example only, FIG. 1 illustrates a hard disk drive 141 that reads from or writes to non-removable, nonvolatile magnetic media, a magnetic disk drive 151 that reads from or writes to a removable, nonvolatile magnetic disk 152, and an optical disk drive 155 that reads from or writes to a removable, nonvolatile optical disk 156 such as a CD ROM or other optical media. Other removable/non-removable, volatile/nonvolatile computer storage media that can be used in the exemplary operating environment include, but are not limited to, magnetic tape cassettes, flash memory cards, digital versatile disks, digital video tape, solid state RAM, solid state ROM, and the like. The hard disk drive 141 is typically connected to the system bus 121 through a non-removable memory interface such as interface 140, and magnetic disk drive 151 and optical disk drive 155 are typically connected to the system bus 121 by a removable memory interface, such as interface 150.

The drives and their associated computer storage media, discussed above and illustrated in FIG. 1, provide storage of computer-readable instructions, data structures, program modules and other data for the computer 110. In FIG. 1, for example, hard disk drive 141 is illustrated as storing operating system 144, application programs 145, other program modules 146 and program data 147. Note that these components can either be the same as or different from operating system 134, application programs 135, other program modules 136, and program data 137. Operating system 144, application programs 145, other program modules 146, and program data 147 are given different numbers herein to illustrate that, at a minimum, they are different copies. A user may enter commands and information into the computer 20 through input devices such as a tablet, or electronic digitizer, 164, a microphone 163, a keyboard 162 and pointing device 161, commonly referred to as mouse, trackball or touch pad. Other input devices not shown in FIG. 1 may include a joystick, game pad, satellite dish, scanner, or the like. These and other input devices are often connected to the processing unit 120 through a user input interface 160 that is coupled to the system bus, but may be connected by other interface and bus structures, such as a parallel port, game port or a universal serial bus (USB). A monitor 191 or other type of display device is also connected to the system bus 121 via an interface, such as a video interface 190. The monitor 191 may also be integrated with a touch-screen panel or the like. Note that the monitor and/or touch screen panel can be physically coupled to a housing in which the computing device 110 is incorporated, such as in a tablet-type personal computer. In addition, computers such as the computing device 110 may also include other peripheral output devices such as speakers 195 and printer 196, which may be connected through an output peripheral interface 194 or the like.

The computer 110 may operate in a networked environment using logical connections to one or more remote computers, such as a remote computer 180. The remote computer 180 may be a personal computer, a server, a router, a network PC, a peer device or other common network node, and typically includes many or all of the elements described above relative to the computer 110, although only a memory storage device 181 has been illustrated in FIG. 1. The logical connections depicted in FIG. 1 include a local area network (LAN) 171 and a wide area network (WAN) 173, but may also include other networks. Such networking environments are commonplace in offices, enterprise-wide computer networks, intranets and the Internet. For example, in the present invention, the computer system 110 may comprise source machine from which data is being migrated, and the remote computer 180 may comprise the destination machine. Note however that source and destination machines need not be connected by a network or any other means, but instead, data may be migrated via any media capable of being written by the source platform and read by the destination platform or platforms.

When used in a LAN networking environment, the computer 110 is connected to the LAN 171 through a network interface or adapter 170. When used in a WAN networking environment, the computer 110 typically includes a modem 172 or other means for establishing communications over the WAN 173, such as the Internet. The modem 172, which may be internal or external, may be connected to the system bus 121 via the user input interface 160 or other appropriate mechanism. In a networked environment, program modules depicted relative to the computer 110, or portions thereof, may be stored in the remote memory storage device. By way of example, and not limitation, FIG. 1 illustrates remote application programs 185 as residing on memory device 181. It will be appreciated that the network connections shown are exemplary and other means of establishing a communications link between the computers may be used.

Data Access Model

The present invention generally operates in an architecture/platform that connects network-based (e.g., Internet-based) applications, devices and services, and transforms them into a user's personal network which works on the user's behalf, and with permissions granted by the user. To this end, the present invention is generally directed to schema-based services that maintain user, group, corporate or other entity data in a commonly accessible virtual location, such as the Internet. The present invention is intended to scale to millions of users, and be stored reliably, and thus it is likely that a user's data will be distributed among and/or replicated to numerous storage devices, such as controlled via a server federation. As such, while the present invention will be generally described with respect to an identity-centric model that enables a user with an appropriate identity and credentials to access data by communicating with various core or other services, it is understood that the schema-based services described herein are arranged for handling the data of millions of users, sorted on a per-user-identity basis. Note that while “user” is generally employed herein for simplicity, as used herein the term “user” is really a substitute for any identity, which may be a user, a group, another entity, an event, a project, and so on.

As generally represented in FIG. 2, a data access model 200 includes a generic navigation module 202 through which applications 204 and the like may access a wide variety of identity-based data, such as maintained in an addressable store 206. To access the data, a common set of command methods may be used to perform operations on various data structures that are constructed from the data in the addressable store 206, even though each of those data structures may represent different data and be organized quite differently. Such command methods may describe generic operations that may be desired on a wide variety of data structures, and include, for example, insert, delete, replace, update, query or changequery methods.

In accordance with one aspect of the present invention and as described in detail below, the data is accessed according to various schemas, with the schemas corresponding to identity-based services through which users access their data. As used herein, a “schema” generally comprises a set of rules that define how a data structure may be organized, e.g., what elements are supported, in what order they appear, how many times they appear, and so on. In addition, a schema may define, via color-coding or other identification mechanisms, what portions of an XML document (that corresponds to the data structure) may be operated on. Examples of such XML-based documents are described below. The schema may also define how the structure of the XML document may be extended to include elements not expressly mentioned in the schema.

As will be understood below, the schemas vary depending on the type of data they are intended to organize, e.g., an email-inbox-related schema organizes data differently from a schema that organizes a user's favorite websites. Further, the services that employ schemas may vary. As such, the generic navigation module 202 has associated therewith a navigation assistance module 208 that includes or is otherwise associated with one or more schemas 210. As will be understood, a navigation assistance module 208 as represented in FIG. 2 corresponds to one or more services, and possesses the information that defines how to navigate through the various data structures, and may also indicate which command methods may be executed on what portions of the data structure. Although in FIG. 2 only one navigation assistance module 208 is shown coupled to the generic navigation module 202, there may be multiple navigation assistance modules that may each specialize as desired. For example each navigation assistance module may correspond to one service. Moreover, although the navigation assistance module 208 is illustrated as a separate module, some or all of the operations of the navigation assistance module 208 may be incorporated into the generic navigation module 202, and vice versa. In one embodiment, the various data structures constructed from the schema and addressable store data may comprise XML documents of various XML classes. In that case, the navigation assistance module 208 may contain a schema associated with each of the classes of XML documents.

The present invention provides a number of schema-based services that facilitate data access based on the identity of a user. Preferably, the user need not obtain a separate identity for each service, but rather obtains a single identity via a single set of credentials, such as with the Microsoft® Passport online service. With such an identity, a user can access data via these services from virtually any network connectable device capable of running an application that can call the methods of a service.

Services and Schemas

“.NET My Services” comprises identity-centric services which may be generally implemented in XML (eXtensible Markup Language) Message Interfaces (XMIs). While the present invention will be described with respect to XML and XMI, it can readily be appreciated that the present invention is not limited to any particular language or set of interfaces. The .NET My Services model essentially corresponds to one implementation of the generic data access model 200 of FIG. 2.

As generally represented in FIG. 3, .NET My Services 300 is implemented as a set of Web services 301–316, each bound to a .NET Identity (PUID, such as a Passport® unique identifier similar to a globally unique identifier when Passport® is the authentication service). The services 301–316 can communicate with one another via a service-to-service communications protocol (SSCP), described below. As also described below, each service presents itself as a set of XML documents that can be manipulated from an application program 202 (FIG. 2) or the like using a set of standard methods and domain-specific methods. To this end, a user device 320 (endpoint) running such application programs connects a user's applications to the services, and the data controlled by those services, such as over the Internet or an Intranet. Note that endpoints can be client devices, applications or services. In keeping with the present invention, virtually any device capable of executing software and connecting to a network in any means may thus give a user access to data that the user is allowed to access, such as the user's own data, or data that a friend or colleague has specified as being accessible to that particular user.

In general, a .NET Identity is an identifier assigned to an individual, a group of individuals, or some form of organization or project. Using this identifier, services bound to that identity can be located and manipulated. A general effect is that each identity (e.g., of a user, group or organization) has tied to it a set of services that are partitioned along schema boundaries and across different identities. As will be understood, the XML-document-centric architecture of .NET My Services provides a model for manipulating and communicating service state that is very different from prior data access models. The XML-document-centric approach, in conjunction with loose binding to the data exposed by the services, enables new classes of application programs. As will also be understood, the .NET My Services model 300 presents the various services 301–316 using a uniform and consistent service and method model, a uniform and consistent data access and manipulation model, and a uniform and consistent security authorization model.

In a preferred implementation, the .NET My Services model 300 is based upon open Internet standards. Services are accessed by means of SOAP (Simple Object Access Protocol) messages containing an XML payload. Service input and output is expressed as XML document outlines, and each of these document outlines conform to an XML schema document. The content is available to a user interacting with the .NET My Services service endpoint 320.

Turning to FIG. 4, in the .NET My Services model, an application 400 requests performance of a method that operates on data structures. The application may make a request that is generic with respect to the type of data structure being operated upon and without requiring dedicated executable code for manipulating data structures of any particular data type. To this end, the application first contacts a special myServices service 314 to obtain the information needed to communicate with a particular service 404, through a set of methods 406 of that service 404. For example, the needed information received from the myServices service 314 includes a URI of that service 404. Note that the service 404 may correspond to essentially any of the services represented in FIG. 3, such as the myDevices service 306.

In an alternate implementation, the services and data may be available on an intranet or the like. In such an event, it may be unnecessary to use the myServices service 314, e.g., if the URI of the desired services are fixed for any user of the intranet. Notwithstanding, a more flexible approach with an intranet may be to have the myServices service that simply provides an intranet URI, such as from a simple lookup table, whereby an administrator and the applications would not be bound to anything fixed.

The service 404 includes or is otherwise associated with a set of methods 406 including standard methods 408, such as to handle requests directed to insert, delete, replace, update, query or changequery operations on the data. The set of methods of a particular service may also include service specific methods 410. In general, the only way in which an application can communicate with a service are via that service's methods.

Each service includes service logic 412 for handling requests and providing suitable responses. To this end, the service logic performs various functions such as authorization, authentication, and signature validation, and further limits valid users to only the data which they are permitted to access. The security aspect of a service is not discussed herein, except to note that in general, for otherwise valid users, the user's identity determines whether a user can access data in a requested manner. To this end, a roleMap 414 comprising service-wide roleList document templates 415 and scopes (e.g., part of the overall service's schema 416), in conjunction with user-based data maintained in an addressable store 418, determines whether a particular requested method is allowed, e.g., by forming an identity-based roleList document 420. If a method is allowed, the scope information in the roleMap 414 determines a shape of data to return, e.g., how much content is allowed to be accessed for this particular user for this particular request. The content is obtained in accordance with a content document 422 in the service's schema 416 and the actual user data corresponding to that content document in the addressable store 418. In this manner, a per-identity shaped content document 424 is essentially constructed for returning to the user, or for updating the addressable store, as appropriate for the method. Note that FIG. 4 includes a number of ID-based roleList documents and ID-based content documents, to emphasize that the service 406 is arranged to serve multiple users. Also, in FIG. 4, a system document 426 is present as part of the schema 416, as described below.

Returning to FIG. 3, in one implementation, access to .NET My Services 300 is accomplished using SOAP messages formatted with .NET My Services-specific header and body content. Each of the .NET My Services will accept these messages by means of an HTTP POST operation, and generate a response by “piggy-backing” on the HTTP Response, or by issuing an HTTP POST to a .NET My Services response-processing endpoint 320. In addition to HTTP as the message transfer protocol, .NET My Services will support raw SOAP over TCP, a transfer protocol known as Direct Internet Message Encapsulation (or DIME). Other protocols for transferring messages are feasible.

Because .NET My Services are accessed by protocol, no particular client-side binding code, object models, API layers, or equivalents are required, and are thus optional. The .NET My Services will support Web Services Description Language (WSDL). It is not mandatory that applications wishing to interact with .NET My Services make use of any particular bindings, and such bindings are not described herein. Instead, the present invention will be generally described in terms of messages that flow between requesters of a particular service and the service endpoints. In order to interact with .NET My Services, a service needs to format a .NET My Services message and deliver that message to a .NET My Services endpoint. In order to format a message, a client needs to manipulate XML document outlines, and typically perform some simple, known (public-domain) cryptographic operations on portions of the message.

In accordance with one aspect of the present invention, and as described in FIG. 4 and below, in one preferred implementation, services (including the myDevices service 306) present three logical XML documents, a content document 422, roleList document 415 (of the roleMap 414), and a system document 426. These documents are addressable using .NET My Services message headers, and are manipulated using standard .NET My Services methods. In addition to these common methods, each service may include additional domain-specific methods.

Each .NET MyServices service thus logically includes a content document 422, which in general is the main, service-specific document. The schema for this document 422 is a function of the class of service, as will become apparent from the description of the myDevices service's content document below. For example, in the case of the myDevices service 306, the content document presents data in the shape dictated by the .NET My Services .myDevices schema, whereas in the case of the “.NET FavoriteWebSites” service 308, the content document presents data in the shape dictated by a .NET myFavoriteWebSites schema.

Each service also includes a roleList document 415 that contains roleList information, comprising information that governs access to the data and methods exported by the service 404. The roleList document is manipulated using the .NET My Services standard data manipulation mechanisms. The shape of this document is governed by the .NET My Services core schema's roleListType XML data type.

Each service also includes a system document 426, which contains service-specific system data such as the roleMap, schemaMap, messageMap, version information, and service specific global data. The document is manipulated using the standard .NET data manipulation mechanism, although modifications are limited in a way that allows only the service itself to modify the document. The shape of this system document 426 may be governed by the system document schema for the particular service, in that each service may extend a base system document type with service specific information.

As is understood, the present invention is generally based on schemas, which in general comprise a set of rules or standards that define how a particular type of data can be structured. Via the schemas, the meaning of data, rather than just the data itself, may be communicated between computer systems. For example, a computer device may recognize that a data structure that follows a particular address schema represents an address, enabling the computer to “understand” the component part of an address. The computer device may then perform intelligent actions based on the understanding that the data structure represents an address. Such actions may include, for example, the presentation of an action menu to the user that represents things to do with addresses. Schemas may be stored locally on a device and/or globally in a federation's “mega-store.” A device can keep a locally-stored schema updated by subscribing to an event notification service (in this case, a schema update service) that automatically passes messages to the device when the schema is updated. Access to globally stored schemas is controlled by the security infrastructure.

General Schema Commonality

The .NET My Services data is defined using annotated XSD schema files. The XSD files accurately type the data, but since XSD is a verbose and complex language, it is not a particularly efficient way to convey structure and meaning. Thus, for purposes of simplicity herein, the myDevices schemas are described below in terms of schema outlines with accompanying element/attribute descriptions. These document outlines accurately show the structure of the data contained within a service. However, because the present application is not viewable in color, the nodes, elements and/or attributes of the schema outlines (which may be described as bold blue, or blue), are represented in the schema outlines as boldface type. Those described as underlined red, or red, are represented as underlined type, while others referred to as black are represented in normal type.

The meaning of these bold (blue), underlined (red) and normal (black) items has significance with respect to the data model and to the data language that accesses and manipulates the data (e.g., via the insert, delete, replace, update, query, changequery or other methods). For example, each document described below contains a root element having an element name that matches that of the service, e.g., the myDevices service has a root element named myDevice. The .NET My Services name for this item is the root.

Documents contain elements that resemble first-class top-level objects, including, for example, <catDef/>, <myApplicationsSettings/> (other another name as appropriate) and <order/>. Such items are denoted in the outlines as bold (blue), and may be identified using an <xdb:blue/> tag. Bold (blue) items define major blocks of data within a service. These node sets are directly addressable by an identifier attribute, and their change status is tracked through a changeNumber attribute. Top-level bold blue items may be considered objects. As seen below, some bold (blue) objects contain nested bold blue objects. They usually contain frequently changing underlined (red) properties, which reduces the amount of synchronization traffic. Nested bold (blue) items may be considered property groups.

Each bold blue item contains one or more underlined (red) items which are elements or attributes. These items may be identified using the <xdb:red/> tag. These items are special in that they may be used within predicates (filters) to aid in xdb:bold blue selection. These items are also directly addressable and may be manipulated directly by the data manipulation language.

Each colored red element may contain one or more non-colorized elements and attributes, which are valid and semantically meaningful XML items in the service document. Such items are opaque to the data language. These uncolored (i.e., non-bold or underlined) elements and attributes may not be addressed directly, may not be selected in a node selection operation, and may not be used in a predicate node test. Note that if one of these items is in the path to an underlined red item, it may be used in a location step to the underlined red item, but may not be used as the selected node. Note that being opaque does not mean that the item is not considered during schema validation, but rather means that the item may not be used in a predicate, may not be directly addressed, and may not be inserted by itself. As can be readily appreciated, in this manner, the .NET My Services thus limits the granularity of access to nodes within the service document, since only xdb:bold blue and xdb:underlined red marked items are directly addressable, and only those elements and attributes tagged with the xdb:underlined red annotation may be used in predicates to influence node selection. Using this technique, the .NET My Services storage system can efficiently manage indexes, increase the performance of node selection, partially shred the document data, and in general (because the node selections are well defined) fine-tune the node selection logic on a per-xdb:blue basis. The primary purpose of the xdb:blue is to define a base-level XML object that is designed to be operated on as a unit. The primary purpose of the xdb:red items is to aid in the selection of xdb:bold blues. The xdb:red items may be changed by the data language primitives so some level of fine-grained manipulation of the data is available, but only in very limited ways.

Bold blue items have unique IDs, which are usually assigned by .NET My Services, and are returned from update operations within the new blueId node. In all cases, the order of xxxBold blue follows the pre-order traversal of the document XML tree. Item IDs are UUIDs in the following format (h stands for a hexadecimal digit): hhhhhhhh-hhhh-hhhh-hhhh-hhhhhhhhhhhh.

In addition to identifiers, names and change numbers, nodes and especially red nodes may include creator identifiers, category information, and {any} fields. Category information enables data to be grouped and/or distinguished in some way, such as to share certain calendar information with golf buddies, send an email to immediately family, designate things such as which telephone number is the user's primary number, e.g., if a user has a second home, and so on. Fields of type “any” may comprise fully-typed, namespace-qualified fields that contain any type of content (e.g., free-form XML) therein. Such “any” fields thus allow extensibility of the schema, yet maintain the defined structure of a schema.

In one implementation, the core data-manipulation language implemented by the .NET My Services includes an insertRequest, or insert message. This primitive inserts any schema-valid XML fragment into a selected context, thereby changing the existing state of the document. A queryRequest, or message, retrieves data, such as to retrieve a document. Multiple queries may be specified in one request, and queries that select nothing are considered successful. It is possible to assert that the number of nodes in the selection falls in a given range. This is expressed using minOccurs and maxOccurs attributes. If a minOccurs/maxOccurs test fails on any node, the request is considered unsuccessful. Note that this is different from a failure code, which would be returned, for example, for a malformed request.

A deleteRequest primitive deletes the selected nodes and all their children. Note that, just like for other requests, attributes may be selected as well as elements. Empty selections result in successful operations, similar to Query. The minOccurs/maxOccurs tests are supported wherever select is allowed.

A replaceRequest primitive (replace message) is designed to replace the content of each of the selected nodes with the specified new content. Selected nodes themselves are not affected in any way. This may be considered as an atomic delete of the content of the selected node, followed by an insert. The content (text, attributes, elements) in the selected nodes are replaced with the new item specified in this message. The node type of the selected node and of the replacement node are thus required to be the same. The changequery request essentially returns result comrpising data that has changed.

As mentioned above, each of the services includes a RoleList document and scope information that describes which users have what type of access to which data. For example, a data owner will have read/write access to his or her own data, and can provide various types of rights to that data to other users based on their IDs, (e.g., read only to some users, read write to others). Each role list identifier may be associated with a scope, by which the kinds of data stored according to a given schema can be controlled per user. For example, a user can give a friend (with one identity) access via a service to a home telephone number, home address and so forth, but can give other users (with other identities) access only to a business telephone number. In general, a scope can be defined such that that it includes everything except any specifically listed items, or excludes everything except any specifically listed items.

myDevices

The .NET devices (myDevices) web service is a centralized store for attributes of .NET-compatible computing devices associated with a single identity. The .NET Devices service is designed to store a combination of characteristics about primarily mobile communication devices, along with the carriers which provision those devices. This service is primarily designed to allow notifications, messages and other real-time communications to be delivered to a wide variety of devices on various transports. By providing this service, applications, web sites and other third party services can easily query the list and capabilities of all computers, cell phones, PDAs, and so on associated with an individual. Such elements as device screen size, screen color depth, input methods, processor type are stored and can be queried by any allowed service.

By providing for this centralized store, applications can easily query the native capabilities of devices associated with an individual and make intelligent decisions around shaping content or notifications specifically for the unique attributes of a specific device. They can do this even if the device is inaccessible, turned off, or transiently connected to the internet.

The present invention provides a cross-referencing of a globally unique device identification number throughout the other .NET services, such as the electronic end point for email messages, notifications or presence information. In addition, the globally unique device ID number is also the same as used by the Universal Plug and Play forum (http://www.upnp.org), so as to provide interoperability with other UPnP devices. The present invention also provides a “last known good” state of the current device state, as stored on the central server, even if the device is turned off, and provides key information about how the device is actually being used at the current moment for other high value .NET services, such as the myNotifications service. The present invention further provides a central point of administration for all devices associated with a person, easily enabling them to add, delete or change ownership of devices (such as when selling an AutoPC-equipped car), and provides an extensibility mechanism so that third parties can decorate the schema with additional elements unique to their specific circumstances, such as adding a variety of cellular network-specific attributes to a cell phone device.

FIG. 5 generally provides an example of .NET devices (myDevices) functionality. For example, a user purchases a new .NET-aware cell phone, such as the DEVICE₁ 501 in FIG. 5. When first activated and a Passport ID (PUID) entered, the device asks whether to register the phone with the user's Personal.NET service. If affirmative, the phone dumps its current physical attributes (screen size, network transports, etc) to the central myDevices Service 306. This device then appears as one of possibly many devices in the device administration web page associated with your identity. The user can then grant or deny access to the information about that device via the various .NET roles you may have previously created (“Friend”, “Family”, “Business Colleague”, and so forth).

Assume that a Web Site₁ 511 now needs to send the user an important email message, and has decided that the user is likely to quickly get the message on the cell phone, i.e., the device 501. Assuming it has the necessary permissions, the Web Site₁ 511 queries the central myDevices service 306 and looks up the physical attributes of the cell phone.

The Web Site₁ now formulates an HTML-based email message specifically tailored to the physical attributes of that device 501, to be delivered by the primary SMTP transport as listed for that device via the myPresence .NET service (e.g., the electronic end point as listed for the SMTP transport). If the cell phone was out of network range, or turned off, then the email message is queued for later delivery by the network transport of that device.

Alternatively, the following may scenario happen when the Web Site₁ 511 wants to send the user an important email message. The myAlerts web service (Web Service₂ 512 in FIG. 5) queries the myDevices service 500 to learn which items which will help it in the intelligent routing of pop-up notifications to a most-likely-to-be seen device. One of these may include the most recent timestamp associated with each device schema. This, combined with other information (such as the current list of events in the user's myCalendar service) can indicate which device is (or devices are) most likely to be online and accessible at the moment. Another of these items may include a currently preferred alert mode (flash, vibrate, buzz, chirp or the like) for when notifications land on the device, for the appropriate formatting of the content. Although the device will generally be the final decision authority on how notifications will be displayed, it is of great use if the notifications service knows in advance of notification delivery to make informed decisions on the best way to shape and route the notification.

Yet another valuable item to know is the current network transport bandwidth. This will help determine whether to route large email messages or pictures to that device.

With some or all of the desired information, the myAlerts service 301 then generates an appropriately formatted real-time notification message based upon the above inputs and sends it along to the device via the electronic end point transports, e.g., as listed in the myPresence service 312.

In general, a device schema describes metadata that represents information about one or more devices (e.g., user devices) that are enlisted or provisioned by a service. The device schema represents the data directed to various device properties, including information used by an information agent service about the connection, the rendering abilities, and interactive abilities of devices, as generally described in U.S. patent application Ser. No. 10/099,467, filed Mar. 14, 2002. An example outline of how a device schema may be arranged, along with the information that may be represented thereby, is represented in TABLES 1–3 below:

TABLE 1 Device Schema Device Name, device type, uuid Connection information Bandwidth To/from device Media rendering abilities uri Text, graphics (x,y), audio, etc. Local notification manager properties Local policy configuration Path to local policy information Alerting modalities Basic alerting Visual cues: type Tone type x, vol. y Silent Rich client with alerting api/UI Alternate notification rendering UI Journal ability Memory capacity User interaction support Device genre Small screen with functions { } Rich client Usage preferences Typical viewing distance Typical input methodology User input capabilities Special inputs Text input- full keyboard, alternate Cursor control Speech Audio Videocapture Client UI components Local UI code and interfaces e.g., Windows client modules, API Backchannel and relay External messaging backchannel Backchannel properties Events, class Confirmation abilities Local receipt User confirmation Device context status e.g., In use, in motion, app status, activity status, last use Local relay for platform services APIs to local client services Classes

TABLE 2 Alternative Device Schema Outline <!-- Device schema -->[may be inherited to myNotifications schema] <device id=“ . . . ”> <name xml:lang=“ . . . ” dir=“ . . . ”>1 . . . 1</name> <type>1 . . . 1</type> <connectionInformation> <!-- --> </connectionInformation> <bandwidth to=“ . . . ” from=“ . . . ”/> <uri> <text type=“plain|html”/> <graphics x=“ . . . ” y=“ . . . ” colors=“ . . . ”/> <audio/> <messageLimit size=“ . . . ” onExceed=“chunk|truncate|compress” /> <!-- Local notification manager properties Local policy configuration Path to local policy configuration --> <alert type=“???” tone=“true|false” volume=“ . . . ” alternateRenderingUi=“???”>0 . . . unbounded </alert> <journal memory=“ . . . ”>0 . . . 1</journal> <userInteraction> <!-- shared schema from above --> <bandwidth to=“ . . . ” from=“ . . . ”/> <uri/><!-- what is this? --> <text type=“plain|html”/> <graphics x=“ . . . ” y=“ . . . ” colors=“ . . . ”/> <audio/> <userInput keyboard=“none|full|alternate” cursorControl=“ . . . ” speech=“none|[name or uri of speech engine” audio=“ . . . ” video=“ . . . ” /> <clientUi path=“ . . . ”></clientUi> {any} </userInteraction>

TABLE 3 XML-formatted simple Device Schema <myDevices> <device name= “ ” uuid=“ ”> <extension type= “ ” uuid=“ ”></extension> <friendly name/> <physicalAttributes> <deviceType/> <cpuFamily name = “ ”/> <operatingSystem> <osName/> <osVersion/> <osLanguage/> </operatingSystem> <inputMethods/> <renderingMethods> <textOnly/> <graphicsHeight/> <graphicsWidth/> <graphicsColorDepth /> <audio/> <alertingModes/> </renderingMethods> <network> <transport name =“ ” address=“ ” active =“ ”> <downstreamBandwidth/> <upstreamBandwidth/> </transport> </network> </physicalAttributes> <informationAttributes> <preferredViewingDistance/> <preferredInputMethod/> <preferredAlertMode/> <userLanguage/> </informationAttributes> </device> </myDevices>

In this manner, a Devices schema enables the information agent service to modify the notification message for the device based on various criteria, including its type, CPU, operating system, audio and video capabilities, rendering methods, network transport capabilities and so forth. An XML-based device schema is described below.

myDevices/Roles

The myDevices service controls access by using the rt0, rt1, rt2, rt3 and rt99 roleTemplates, using the following scopes:

scope allElements <hs:scope id=7215df55−e4af−449f−a8e4−72a1f7c6a987> <hs:shape base=t> </hs:shape> </hs:scope> scope onlySelfElements <hs:scope id=a159c93d−4010−4460−bc34−5094c49c1633> <hs:shape base=nil> <hs:include select=//*[@creator=‘$callerId’]/> </hs:shape> </hs:scope> scope onlySelfSubscriptionElements <hs:scope id=b7f05a6d−75cd−4958−9dfb−f532ebb17743> <hs:shape base=nil> <hs:include select=//subscription[@creator=‘$callerId’]/> </hs:shape> </hs:scope> scope onlyPublicElements <hs:scope id=da025540−a0c0−470f−adcf−9f07e5a5ec8f> <hs:shape base=nil> <hs:include select=//*[cat/@ref=‘hs:public’]/> <hs:include select=//subscription[@creator=‘$callerId’]/> </hs:shape> </hs:scope>

The myDevices roleTemplate rt0 role gives complete read/write access to the information within the content document of the service being protected through this roleTemplate. The following table illustrates the available methods and the scope in effect when accessing the myDevices service through that method while mapped to this roleTemplate:

TABLE myDevices roleTemplate rt0 method scope/name Query allElements Insert allElements Replace allElements Delete allElements Update allElements

The myDevices roleTemplate rt1 role gives completed read access to all information within the content document of the service being protected through this role Template. Applications mapping to this role also have a limited ability to write information in the content document. They may create nodes in any location, but may only change/replace, or delete nodes that they created. The following table illustrates the available methods and the scope in effect when accessing the myDevices service through that method while mapped to this roleTemplate:

TABLE myDevices roleTemplate rt1 method scope/name Query allElements Insert onlySelfElements Replace onlySelfElements Delete onlySelfElements

The myDevices roleTemplate rt2 role gives complete read access to all information within the content document of the service being protected through this roleTemplate. Applications mapping to this role also have a limited ability to write access and are only able to create and manipulate their own subscription nodes. The following table illustrates the available methods and the scope in effect when the myDevices service through that method while mapped to this roleTemplate:

TABLE myDevices roleTemplate rt2 method scope/name Query allElements Insert onlySelfSubscriptionElements replace onlySelfSubscriptionElements Delete onlySelfSubscriptionElements

The myDevices roleTemplate rt3 role gives limited read access to information within the content document that is categorized as “public.” The following table illustrates the available methods and the scope in effect when accessing the myDevices service through that method while mapped to this roleTemplate:

myDevices roleTemplate rt3 method scope/name Query onlyPublicElements

The myDevices roleTemplate rt99 blocks access to the content document. Note that lack of a role in the roleList has the same effect as assigning someone to rt99.

myDevices/Content

The content document is an identity centric document, with its content and meaning a function of the user identifier (puid) used to address the service. Accessing the document is controlled by the associated roleList document. The following table comprises a schema outline that illustrates the layout and meaning of the information found in the content document for the myDevices service:

<m:myDevices changeNumber=“ . . . ” instanceId=“ . . . ” xmlns:m=“http://schemas.microsoft.com/hs/2001/10/myDevices” xmlns:hs=“http://schemas.microsoft.com/hs/2001/10/core”>₁ ₁ <m:device changeNumber=“ . . . ” id=“ . . . ” creator=“ . . . ”>_(0 unbounded) <m:cat ref=“ . . . ”>_(0 unbounded)</m:cat> <m:deviceId>₁ ₁</m:deviceId> <m:carrierId>₁ ₁</m:carrierId> <m:name xml:lang=“ . . . ” dir=“ . . . ”>₁ ₁</m:name> <m:address>_(0 unbounded)</m:address> {any} </m:device> <m:subscription changeNumber=“ . . . ” id=“ . . . ” creator=“ . . . ”>_(0 unbounded) <hs:trigger select=“ . . . ” mode=“ . . . ” baseChangeNumber=“ . . . ”>_(1.1)</hs:trigger> <hs:expiresAt>₀ ₁</hs:expiresAt> <hs:context uri=“ . . . ”>₁ ₁{any}</hs:context> <hs:to>₁ ₁</hs:to> </m:subscription> {any} </m:myDevices>

The meaning of the attributes and elements shown in the table are set forth below, wherein in the syntax used in the table, boldface type corresponds to a blue node, and underlined type to a red node, as described above, and the minimum occurrence information (0, 1) indicates whether an element or attribute is required or optional, and maximum occurrence information (1, unbounded) indicates whether one or many are possible.

The /myDevices (minOccurs=1 maxOccurs=1) element encapsulates the content document for the .NET Devices service. The /myDevices/@changeNumber (minOccurs=0 maxOccurs=1) changeNumber attribute is designed to facilitate caching of the element and its descendants. This attribute is assigned to this element by the .NET My Services system. The attribute is read-only to applications. Attempts to write this attribute are silently ignored.

The /myDevices/@instanceId (string minOccurs=0 maxOccurs=1) attribute is a unique identifier typically assigned to the root element of a service. It is a read-only element and assigned by the .NET My Services system when a user is provisioned for a particular service.

The /myDevices/device (minOccurs=0 maxOccurs=unbounded) element defines a communication device within the .NET Devices service. Each device is an extensible, categorized item containing the name of the device encoded as a URI, the name of the carrier that services the device encoded as a URI, a friendly name for the device, a list of URIs that may be used to address the device, and so on.

Devices are categorized into classes using simple categorization. For instance, a device is classified as a cellPhone through the “system#callPhone” categorization. Additionally, a device is marked as a primary device through categorization using the “system#primary” category reference.

A validated device is one that has been digitally signed and certified by some entity. .NET My Services accommodates this by allowing the use of extension elements holding certified digital signatures, or holding references to verification services that may validate a node on the fly.

The /myDevices/device/@changeNumber (minOccurs=0 maxOccurs=1) changeNumber attribute is designed to facilitate caching of the element and its descendants. This attribute is assigned to this element by the .NET My Services system. The attribute is read-only to applications. Attempts to write this attribute are silently ignored.

The /myDevices/device/@id (minOccurs=0 maxOccurs=1) attribute is a globally unique ID assigned to this element by .NET My Services. Normally, .NET My Services will generate and assign this ID during an insertRequest operation, or possibly during a replaceRequest. Application software can override this ID generation by specifying the useClientIds attribute in the request message. Once an ID is assigned, the attribute is read-only and attempts to write it are silently ignored.

The /myDevices/device/@creator (string minOccurs=0 maxOccurs=1) attribute identifies the creator in terms of userId, appId, and platformId of the node.

The /myDevices/device/cat (minOccurs=0 maxOccurs=unbounded) element is used to categorize the element that contains it by referencing a global category definition in either the .NET Categories service section, described above, an external resource containing category definitions, or by referencing an identity centric category definition in the content document of the .NET Categories service for a particular puid.

The /myDevices/device/cat/@ref (anyURI minOccurs=0 maxOccurs=1) attribute references a category definition (<catDef/>) element using the rules outlined in the myCategories section described above.

The /myDevices/device/deviceId (anyURI minOccurs=1 maxOccurs=1) element contains the device name/id in a URI form. This element is encoded as a URI to allow much richer and extensible naming for the device than can be expressed using a simple uuid. The URI name will be of the form http://mydevices.microsoft.com/carrierID/deviceID#9c20f0e8-c0ef-472d-8bec-4cc6f8b0f456.

The /myDevices/device/carrierID (anyURI minOccurs=1 maxOccurs=1) element contains the URI of the carrier that is responsible for servicing this device. The element is encoded as a URI. Which allows for both uuid: based identification of the carrier as well as richer identification mechanisms.

The /myDevices/device/name (string minOccurs=1 maxOccurs=1) element contains a user-readable, not necessarily unique friendly name for the device. The /myDevices/device/name/@xml:lang (minOccurs=1 maxOccurs=1) required attribute is used to specify an ISO 639 language code or an ISO 3166 country code as described in RFC 1766. The value of this attribute indicates the language type of the content within this element. The /myDevices/device/name/@dir (string minOccurs=0 maxOccurs=1) optional attribute specifies the default layout direction for the localized string. Valid values are rtl (right to left), and ltr (left to right).

The /myDevices/device/address (anyURI minOccurs=0 maxOccurs=unbounded) element contains addresses in the form of URI's that may be used to address this device. For example, if the device is addressable through email, an address entry of “mailto:someone@microsoft.com” may appear in this element. If the device is also addressable through an http gateway, an additional address of “http://microsoft.com/somepath/someid” may be specified in this element. This element is repeated for each address that may be used to address the device.

The /myDevices/device/{any} (minOccurs=0 maxOccurs=unbounded) allows for extensibility of this schema.

The myDevices content document include a subscription node that essentially takes action when items change, such as to propagate information about the change to other services.

The /myDevice/subscription (minOccurs=0 maxOccurs=unbounded) element defines a subscription node that is designed to be an xdb:blue node which when placed in a content document causes a subscription to be registered, (wherein as used herein, the string “myDevice” referred to in this section can be replaced by an appropriate service name, e.g., “myApplicationSettings” or “myDevice” or “myWallet” and so forth). A subscription contains a trigger element which selects a scope of coverage. When items that are under this scope of coverage change, a subscriptionResponse message is generated and sent to the specified destination address.

The /myDevice/subscription/@changeNumber (minOccurs=0 maxOccurs=1) changeNumber attribute is designed to facilitate caching of the element and its descendants. This attribute is assigned to this element by the .NET My Services system, and the attribute is read-only to applications; attempts to write this attribute are silently ignored. The /myDevice/subscription/@id (minOccurs=0 maxOccurs=1) attribute is a globally unique ID assigned to this element by .NET My Services. Normally, .NET My Services will generate and assign this ID during an insertRequest operation, or possibly during a replaceRequest. Application software can override this ID generation by specifying the useClientlds attribute in the request message. Once an ID is assigned, the attribute is read-only and attempts to write it are silently ignored.

The /myDevice/subscription/@creator (string minOccurs=0 maxOccurs=1) attribute identifies the creator in terms of userId, appId, and platformId of the node. The /myDevice/subscription/trigger (minOccurs=1 maxOccurs=1) includes the /myDevice/subscription/trigger/@select (string minOccurs=0 maxOccurs=1) item, which specifies an XPATH expression that specifies the nodes that are to be selected and watched for changes. The selection may only select xdb:blue nodes, as described above. A s changes in this node set occur, they trigger the generation of a subscription message. These messages are then sent to the SOAP receiver listed in the “to” element.

The /myDevice/subscription/trigger/@mode (string minOccurs=0 maxOccurs=1) attribute specifies whether or not the content of the changes that triggered the subscription are delivered in the subscription message, or if the message simply indicates that something changed under the trigger. The attribute may comprise includeData, namely that the data that changed and caused the subscription to trigger is included in the subscription message. Note that deleted nodes are specified by their id, not by value. Alternatively the attribute may comprise excludeData, whereby the data that changed, causing the subscription to trigger, is not included in the subscription message.

The /myDevice/subscription/trigger/@baseChangeNumber (minOccurs=0 maxOccurs=1) attribute specifies the changeNumber value that the trigger is relative to. All changes between the specified change number, and the current state of the document relative to the selection are transmitted as subscription messages. This allows a client application to establish a subscription relative to some baseline. As in changeQuery, if the baseChangeNumber is way out of date relative to the current state of the document, and the service can not supply the changes in the subscription message, the subscription insert is rejected. A value of zero (0) means that the current values of the selected nodes are transmitted in the subscription message.

The /myDevice/subscription/expiresAt (dateTime minOccurs=0 maxOccurs=1) optional element specifies an absolute time after which the subscription is no longer active. The subscription node is automatically removed when the subscription expires. If this element is missing, the subscription does not expire. The /myDevice/subscription/context (minOccurs=1 maxOccurs=1) element returns the context element from the original subscription. Applications should use this element to correlate the subscription response with one of their subscriptions.

The /myDevice/subscription/context/@uri (anyURI minOccurs=0 maxOccurs=1) attribute specifies the URI value chosen by the subscriber that is associated with this subscription. The /myDevice/subscription/context/{any} (minOccurs=0 maxOccurs=unbounded) including the /myDevice/subscription/to (anyURI minOccurs=1 maxOccurs=1) attribute specifies the location that is to receive the subscription message. The value of this element may be hs:myAlerts, whereby this URI indicates that generated subscription messages are to be delivered inside the body of a notification and delivered to the default .NET Alerts service of the creator. Alternatively, the value may be protocol://service, whereby this URI indicates that generated subscription messages are delivered to the specified service at the domain of the creator's platformId. For example, a platformId indicating microsoft.com, and a value in this element of http://subscriptionResponse would cause delivery of the subscription message to http://subscriptionResponse.microsoft.com. If this value is not specified, then the subscription message is delivered as a notification to the “creator's” .NET Alerts service. The /myDevice/{any} (minOccurs=0 maxOccurs=unbounded) field allows for extensibility.

MyDevices/System

The system document is a global document for each service, having content and meaning that is independent of the puid used to address the service. The document is read only to all users. Each system document contains a set of base items common to each of the .NET My Services described herein, and is optionally extended by each service to include service-specific global information. The following schema outline illustrates the layout and meaning of the information found in the myDevices system document:

TABLE /MyDevices/ system <sys:system changeNumber=“ . . . ” instanceId=“ . . . ” xmlns:hs=“http://schemas.microsoft.com/hs/2001/10/core” xmlns:sys=“http://schemas.microsoft.com/hs/2001/10The /MyDevices/system”>₁ ₁ <hs:systemVersion changeNumber=“ . . . ” id=“ . . . ” creator=“ . . . ”>₁ ₁ <hs:version majorVersion=“ . . . ” minorVersion=“ . . . ” buildNumber=“ . . . ” qfe=“ . . . ”>₁ ₁ <hs:productReleaseName>₁ ₁</hs:productReleaseName> <hs:productImplementationName>₁ ₁</hs:productImplementationName> </hs:version> <hs:buildDate>₁ ₁</hs:buildDate> <hs:buildDetails machine=“ . . . ” branch=“ . . . ” type=“ . . . ” official=“ . . . ”>₁ ₁</hs:buildDetails> </hs:systemVersion> <hs:roleMap changeNumber=“ . . . ” id=“ . . . ” creator=“ . . . ”>_(1 .1) <hs:scope id=“ . . . ”>_(0 unbounded) <hs:name xml:lang=“ . . . ” dir=“ . . . ”>_(0 unbounded)</hs:name> <hs:shape base=“ . . . ”>₁ ₁ <hs:include select=“ . . . ”>_(0 unbounded)</hs:include> <hs:exclude select=“ . . . ”>_(0 unbounded)</hs:exclude> </hs:shape> </hs:scope> <hs:roleTemplate name=“ . . . ” priority=“ . . . ”>_(0 unbounded) <hs:fullDescription xml:lang=“ . . . ” dir=“ . . . ”>₀ ₁</hs:fullDescription> <hs:method name=“ . . . ” scopeRef=“ . . . ”>_(0 unbounded)</hs:method> </hs:roleTemplate> </hs:roleMap> <hs:methodMap changeNumber=“ . . . ” id=“ . . . ” creator=“ . . . ”>₁ ₁ <hs:method name=“ . . . ”>_(0 unbounded){any}</hs:method> </hs:methodMap> <hs:schemaMap changeNumber=“ . . . ” id=“ . . . ” creator=“ . . . ”>₁ ₁ <hs:schema namespace=“ . . . ” schemaLocation=“ . . . ” alias=“ . . . ”>_(0 unbounded){any}</hs:schema> </hs:schemaMap> <hs:wsdlMap changeNumber=“ . . . ” id=“ . . . ” creator=“ . . . ”>₁ ₁ <hs:wsdl wsdlLocation=“ . . . ”>_(0 unbounded){any}</hs:wsdl> <hs:disco discoLocation=“ . . . ”>_(0 unbounded){any}</hs:disco> <hs:wsil wsilLocation=“ . . . ”>_(0 unbounded){any}</hs:wsil> </hs:wsdlMap> </any> </sys:system>

The meaning of the attributes and elements shown in the preceding sample document outline follow, beginning with /system (minOccurs=1 maxOccurs=1), the element that encapsulates a system document common to the various services. Although each service has its own system document, the common system document attributes and elements are described once, for purposes of simplicity, with service-specific system document attributes and elements specified for each service, below. The /system/@changeNumber (minOccurs=0 maxOccurs=1) attribute is designed to facilitate caching of the element and its descendants. This attribute is assigned to this element by the .NET My Services system. The attribute is read-only to applications. Attempts to write this attribute are silently ignored.

The /system/@instanceId (string minOccurs=0 maxOccurs=1) attribute is a unique identifier typically assigned to the root element of a service. It is a read-only element and assigned by the .NET My Services system when a user is provisioned for a particular service.

The /system/systemVersion (minOccurs=1 maxOccurs=1) element defines version information describing this instance of the .NET MyServices service. The /systemVersion/@changeNumber (minOccurs=0 maxOccurs=1) changeNumber attribute is designed to facilitate caching of the element and its descendants. This attribute is assigned to this element by the .NET My Services system. The attribute is read-only to applications; attempts to write this attribute are silently ignored, (e.g., without generating an error).

The /system/systemVersion/@id (minOccurs=0 maxOccurs=1) attribute is a globally unique ID assigned to this element by .NET My Services. Normally, .NET My Services will generate and assign this ID during an insertRequest operation, or possibly during a replaceRequest. Application software can override this ID generation by specifying the useClientIds attribute in the request message. Once an ID is assigned, the attribute is read-only and attempts to write it are silently ignored.

The /system/systemVersion/@creator (string minOccurs=0 maxOccurs=1) attribute identifies the creator in terms of userId, appId, and platformId of the node. The /system/systemVersion/version (minOccurs=1 maxOccurs=1) element defines major, minor, and build number version information. The /system/systemVersion/version/@majorVersion (string minOccurs=0 maxOccurs=1) attribute specifies the major version number of the .NET MyServices service.

The /system/systemVersion/version/@minorVersion (string minOccurs=0 maxOccurs=1) attribute specifies the minor version number of the .NET MyServices service. The /system/systemVersion/version/@buildNumber (string minOccurs=0 maxOccurs=1) attribute specifies the buildNumber of the .NET MyServices service. The /system/systemVersion/version/@qfe (string minOccurs=0 maxOccurs=1) attribute specifies the qfe version number of the .NET MyServices service. The /system/systemVersion/version/productReleaseName (string minOccurs=1 maxOccurs=1) element defines the major product release string (as in .NET My Services Beta 1, and so on). The /system/systemVersion/version/productImplementationName (anyURI minOccurs=1 maxOccurs=1) element defines the class of the service to differentiate between different implementations.

The /system/systemVersion/buildDate (dateTime minOccurs=1 maxOccurs=1) element defines the date and time that the .NET My Services system was built. The time is in UTC (Z relative) form. The /systemVersion/buildDetails (minOccurs=1 maxOccurs=1) element defines details of the build including the machine that generated the build, the branch id of the software that contributed to the build, the type of build (chk/fre), and if the build was generated by an official build release process.

The /system/systemVersion/buildDetails/@machine (string minOccurs=0 maxOccurs=1) attribute specifies the machine that generated the build. The system/systemVersion/buildDetails/@branch (string minOccurs=0 maxOccurs=1) attribute specifies the software branch id for the source code that contributed to this build. The /system/systemVersion/buildDetails/@type (string minOccurs=0 maxOccurs=1) attribute specifies the type of build. A value of chk indicates that this is a checked or debug build. A value of fre indicates that this is a retail build. The /system/systemVersion/buildDetails/@official (string minOccurs=0 maxOccurs=1) attribute indicates that the build was produced by an official build process (value of yes), or an unofficial process (value of no).

The /system/roleMap (minOccurs=1 maxOccurs=1) element encapsulates all the elements that make up a roleMap, which include document class relative roleTemplate, priority, name, method, and per-method scope. An individual roleTemplate defines the maximum scope of information, and the allowable methods used to access that information for each request mapped into the template. The /system/roleMap/@changeNumber (minOccurs=0 maxOccurs=1) changeNumber attribute is designed to facilitate caching of the element and its descendants. This attribute is assigned to this element by the .NET My Services system. The attribute is read-only to applications. Attempts to write this attribute are silently ignored. The /system/roleMap/@id (minOccurs=0 maxOccurs=1) attribute is a globally unique ID assigned to this element by .NET My Services. Normally, .NET My Services will generate and assign this ID during an insertRequest operation, or possibly during a replaceRequest. Application software can override this ID generation by specifying the useClientIds attribute in the request message. Once an ID is assigned, the attribute is read-only and attempts to write it are silently ignored.

The /system/roleMap/@creator (string minOccurs=0 maxOccurs=1) attribute identifies the creator in terms of userId, appId, and platformId of the node. The /system/roleMap/scope (minOccurs=0 maxOccurs=unbounded) element defines a scope which may be referred to by roles within this roleMap to indicate what portions of the document are visible to this role for the specified method.

The /system/roleMap/scope/@id (minOccurs=0 maxOccurs=1) attribute is a globally unique ID assigned to this element by .NET My Services. Normally, .NET My Services will generate and assign this ID during an insertRequest operation, or possibly during a replaceRequest. Application software can override this ID generation by specifying the useClientIds attribute in the request message. Once an ID is assigned, the attribute is read-only and attempts to write it are silently ignored. The /system/roleMap/scope/name (string minOccurs=0 maxOccurs=unbounded) node includes the /system/roleMap/scope/name/@xml:lang (minOccurs=1 maxOccurs=1) required attribute, which is used to specify an ISO 639 language code or an ISO 3166 country code as described in RFC 1766. The value of this attribute indicates the language type of the content within this element. The /system/roleMap/scope/name/@dir (string minOccurs=0 maxOccurs=1) optional attribute specifies the default layout direction for the localized string. Valid values are rtl (right to left), and ltr (left to right).

The /system/roleMap/scope/shape (minOccurs=1 maxOccurs=1) comprises a shape that defines the node set that is visible through the document when operating through this shape element. The /system/roleMap/scope/shape/@base (string minOccurs=0 maxOccurs=1) attribute specifies the initial set of nodes visible through the shape. A value of t indicates that the shape is initialized to include all possible nodes relative to the shape that is currently in effect. For instance, each role defines a scope containing a shape. When defining a shape for a role, the value t indicates all possible nodes available in the specified document for this role. When defining a shape in an ACL entry, a value of t means all of the nodes visible in the shape for the computed role. When using a shape in a data language (e.g., query, insert, replace and so on) operation, a value of t indicates all of the possible nodes selected by the data language operation (relative to the ACL shape which itself is relative to the role's shape). The value nil indicates the opposite of t, which is the empty node set. Nodes from this set may then be included into the shape.

The /system/roleMap/scope/shape/include (minOccurs=0 maxOccurs=unbounded) element specifies the set of nodes that should be included into the shape relative to the possible set of nodes indicated by the base attribute. The /system/roleMap/scope/shape/include/@select (string minOccurs=0 maxOccurs=1) item specifies an XPATH expression that selects a set of nodes relative to the externally established context. The expression can never travel outside the node-set established by this externally established current context. The expression may match zero or more nodes, and the operation manipulates all selected nodes. The minOccurs and maxOccurs attributes are optional and place restrictions and limitations on the number of nodes selected.

The /system/roleMap/scope/shape/exclude (minOccurs=0 maxOccurs=unbounded) element specifies the set of nodes that should be excluded from the shape relative to the possible set of nodes indicated by the base attribute. The /system/roleMap/scope/shape/exclude/@select (string minOccurs=0 maxOccurs=1) item specifies an XPATH expression that selects a set of nodes relative to the externally established context. The expression can never travel outside the node-set established by this externally established current context. The expression may match zero (0) or more nodes, and the operation manipulates all selected nodes. The minOccurs and maxOccurs attributes are optional and place restrictions and limitations on the number of nodes selected. The /system/roleMap/roleTemplate (minOccurs=0 maxOccurs=unbounded) element encapsulates the definition of a role. The attribute set for this element includes the document class that this roleTemplate refers to, the name of the roleTemplate, and the priority of the roleTemplate.

The /system/roleMap/roleTemplate/@name (string minOccurs=0 maxOccurs=1) element specifies the name of the role. The /system/roleMap/roleTemplate/@priority (int minOccurs=0 maxOccurs=1) element specifies the priority of the roleTemplate which is used to select that actual roleTemplate when the role evaluation determines that the subject maps to multiple roleTemplates.

The /system/roleMap/roleTemplate/fullDescription (string minOccurs=0 maxOccurs=1) element contains a description of this role template which specifies the capabilities a caller will have when accessing information through this role. The /system/roleMap/roleTemplate/fullDescription/@xml:lang (minOccurs=1 maxOccurs=1) required attribute is used to specify an ISO 639 language code or an ISO 3166 country code as described in RFC 1766. The value of this attribute indicates the language type of the content within this element. The /system/roleMap/roleTemplate/fullDescription/@dir (string minOccurs=0 maxOccurs=1) optional attribute specifies the default layout direction for the localized string. Valid values are rtl (right to left), and ltr (left to right).

The /system/roleMap/roleTemplate/method (minOccurs=0 maxOccurs=unbounded) element specifies the methods available within this roleTemplate by name, and by scope. When a subject maps to a roleTemplate, the method in the request must match one of these elements for the message to continue to flow. If the method exists, the data available to the method is a function of the scope referenced by this method combined with an optional scope referenced by the role defined in the roleList.

The /system/roleMap/roleTemplate/method/@name (string minOccurs=0 maxOccurs=1) element specifies the name of the method. The /system/roleMap/roleTemplate/method/@scopeRef (string minOccurs=0 maxOccurs=1) attribute specifies the scope within this document that is in effect for this method. The /system/methodMap (minOccurs=1 maxOccurs=1) element defines the methodMap. While in most cases, the roleMap section contains a definitive list of methods, these methods are likely to be scattered about the roleMap in various templates. This section contains the definitive non-duplicated list of methods available within the service.

The /system/methodMap/@changeNumber (minOccurs=0 maxOccurs=1) changeNumber attribute is designed to facilitate caching of the element and its descendants. This attribute is assigned to this element by the .NET My Services system. The attribute is read-only to applications. Attempts to write this attribute are silently ignored.

The /system/methodMap/@id (minOccurs=0 maxOccurs=1) attribute is a globally unique ID assigned to this element by .NET My Services. Normally, .NET My Services will generate and assign this ID during an insertRequest operation, or possibly during a replaceRequest. Application software can override this ID generation by specifying the useClientIds attribute in the request message. Once an ID is assigned, the attribute is read-only and attempts to write it are silently ignored. The /system/methodMap/@creator (string minOccurs=0 maxOccurs=1) attribute identifies the creator in terms of userId, appId, and platformId of the node.

The /system/methodMap/method (minOccurs=0 maxOccurs=unbounded) element defines a method that is available within this service. The /system/methodMap/method/@name (string minOccurs=0 maxOccurs=1) attribute specifies the name of a method available within the service. The /system/methodMap/method/{any} (minOccurs=0 maxOccurs=unbounded) provides for extensibility. The /system/schemaMap (minOccurs=1 maxOccurs=1) element defines the various schema's that define the data structures and shape of information managed by this service. Each schema is defined by its namespace URI, its location, and a preferred namespace alias.

The /system/schemaMap/@changeNumber (minOccurs=0 maxOccurs=1) changeNumber attribute is designed to facilitate caching of the element and its descendants. This attribute is assigned to this element by the .NET My Services system. The attribute is read-only to applications. Attempts to write this attribute are silently ignored.

The /system/schemaMap/@id (minOccurs=0 maxOccurs=1) attribute is a globally unique ID assigned to this element by .NET My Services. Normally, .NET My Services will generate and assign this ID during an insertRequest operation, or possibly during a replaceRequest. Application software can override this ID generation by specifying the useClientlds attribute in the request message. Once an ID is assigned, the attribute is read-only and attempts to write it are silently ignored.

The /system/schemaMap/@creator (string minOccurs=0 maxOccurs=1) attribute identifies the creator in terms of userId, appId, and platformId of the node. The /system/schemaMap/schema (minOccurs=0 maxOccurs=unbounded) element defines a schema which defines data-structures and the shape of information managed by this service. Multiple schema elements exist for each service, once for each logical grouping of information exposed by the service. The /system/schemaMap/schema/@namespace (anyURI minOccurs=0 maxOccurs=1) attribute specifies the namespace URI of this schema. The /system/schemaMap/schema/@schemaLocation (anyURI minOccurs=0 maxOccurs=1) attribute specifies the location (in the form of a URI) of the resource containing schema. When a schema is reachable through a variety of URIs, one schema element will exist for each location.

The /system/schemaMap/schema/@alias (string minOccurs=0 maxOccurs=1) attribute specifies the preferred alias that should be used if possible when manipulating information covered by this schema in the context of this service. The /system/schemaMap/schema/{any} (minOccurs=0 maxOccurs=unbounded) provides for extensibility. The /system/wsdlMap (minOccurs=1 maxOccurs=1) element defines the wsdlMap for this service. This map includes the location of WSDL documents, DISCO documents, and WSIL documents for this web service. These documents are used by applications to understand the format of messages that may be sent to the various services. The /system/wsdlMap/@changeNumber (minOccurs=0 maxOccurs=1) changeNumber attribute is designed to facilitate caching of the element and its descendants. This attribute is assigned to this element by the .NET My Services system. The attribute is read-only to applications. Attempts to write this attribute are silently ignored.

The /system/wsdlMap/@id (minOccurs=0 maxOccurs=1) attribute is a globally unique ID assigned to this element by .NET My Services. Normally, .NET My Services will generate and assign this ID during an insertRequest operation, or possibly during a replaceRequest. Application software can override this ID generation by specifying the useClientIds attribute in the request message. Once an ID is assigned, the attribute is read-only and attempts to write it are silently ignored. The /system/wsdlMap/@creator (string minOccurs=0 maxOccurs=1) attribute identifies the creator in terms of userId, appId, and platformId of the node.

The /system/wsdlMap/wsdl (minOccurs=0 maxOccurs=unbounded) element is used to specify the location of a WSDL file for this service. Multiple entries may exist pointing to the same file hosted in multiple locations, or to variations on the content within the WSDL files.

The /system/wsdlMap/wsdl/@wsdlLocation (anyURI minOccurs=0 maxOccurs=1) attribute is a URI that specifies the location of the WSDL file. The /system/wsdlMap/wsdl/{any} (minOccurs=0 maxOccurs=unbounded) provides for extensibility.

The /system/wsdlMap/disco (minOccurs=0 maxOccurs=unbounded) element is used to specify the location of a DISCO (web-services discovery) file for this service. Multiple entries may exist pointing to the same file hosted in multiple locations, or to variations on the content within the DISCO files. The /system/wsdlMap/disco/@discoLocation (anyURI minOccurs=0 maxOccurs=1) attribute is a URI that specifies the location of the DISCO file. The /system/wsdlMap/disco/{any} (minOccurs=0 maxOccurs=unbounded) provides extensibility. The /system/wsdlMap/wsil (minOccurs=0 maxOccurs=unbounded) element is used to specify the location of a WSIL file for this service. Multiple entries may exist pointing to the same file hosted in multiple locations, or to variations on the content within the WSIL files. The /system/wsdlMap/wsil/@wsilLocation (anyURI minOccurs=0 maxOccurs=1) attribute is a URI that specifies the location of the WSIL file. The /system/wsdlMap/wsil/{any} (minOccurs=0 maxOccurs=unbounded) provides extensibility.

As can be seen from the foregoing detailed description, there is provided a schema-based profile service that allows users to access their data based on their identities and corresponding roles with respect to the data. The schema-based profile service provides Profile data access independent of the application program and device, and in a centrally-accessible location such as the Internet. The schema-based profile service is extensible to handle extended device information.

While the invention is susceptible to various modifications and alternative constructions, certain illustrated embodiments thereof are shown in the drawings and have been described above in detail. It should be understood, however, that there is no intention to limit the invention to the specific forms disclosed, but on the contrary, the intention is to cover all modifications, alternative constructions, and equivalents falling within the spirit and scope of the invention. 

1. In a computer network, a method performed by a schema-based service for identity-based access to device data, the method comprising, providing an identity-based device schema for access to the device data based upon an associated identity of a user, the identity-based device schema defining how requests to the service are structured and defining device-related elements for structuring logical device documents; providing a plurality of logical device documents associated with respective users, where each logical device document is structured with elements in conformance with the identity-based schema and each describes characteristics or properties of a computing device of its associated user; receiving a data access request directed to device information of a user identified by identity information included with the request, where the request comprises markup language that conforms to the identity-based schema; and in response to the data access request, accessing a logical device document of the requested user based on the identity information included with the request, and manipulating the logical device document.
 2. The method of claim 1 wherein manipulating the logical device document comprises reading data from at least one element in the logical device document.
 3. The method of claim 1 wherein manipulating the logical device document comprises writing data to at least one element in the logical device document.
 4. A computer-readable medium having computer-executable instructions for performing the method of claim
 1. 5. In a computer network, a method performed by a schema-based service, the method comprising, receiving a request to retrieve device data with accessibility to the device data based upon an associated identity of a user, the request including associated user identity information identifying a user of a device corresponding to the requested device data, where the request conforms to schema information that defines how the service is accessed; reading from a data store to obtain, from among device data for a plurality of devices and respective users, device data of the user, where the reading is based on the associated user identity information; constructing a device document including at least part of the read device data, the document and device data being structured with markup language according to schema information defining structure of device documents; and returning the document in response to the request.
 6. The method of claim 4 wherein the schema includes at least one defined field for extending the schema.
 7. A computer-readable medium having computer executable instructions for performing the method of claim
 5. 8. In a computer network in which content is sent from an entity to a recipient device, a method comprising, providing a device-information service, the device-information service providing device data formatted with extensible markup language code according to an identity-based device schema; receiving from the entity a data access request directed to accessing device information based upon an associated identity of a user, the request including associated identity information that identifies the recipient device; and in response to the data access request, using the identity information to obtain device data for from among device data for a plurality of devices and providing the device data for the recipient device, the device data being formatted with extensible markup language according to the identity-based device schema.
 9. The method of claim 8 further comprising, at the entity, receiving the device data and modifying the device data before sending the device data to the recipient device.
 10. The method of claim 9 wherein modifying the device data comprises filtering the device data based on a characteristic of the recipient device such that some of the obtained device data is not provided to the recipient device.
 11. The method of claim 9 wherein modifying the device data comprises filtering the device data based on a rendering capability of the recipient device such that some of the obtained device data is not provided to the recipient device.
 12. The method of claim 9 wherein the device data corresponds to an alert, and wherein modifying the device data comprises filtering the device data based on an alerting capability of the recipient device.
 13. A computer-readable medium having computer-executable instructions for performing the method of claim
 8. 